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http://dx.doi.org/10.15267/keses.2019.38.1.73

An Analysis of the Scientific Problem Solving Strategies according to Knowledge Levels of the Gifted Students  

Kim, Chunwoong (Okdong Elementary School)
Chung, Jungin (Cheongju National University of Education)
Publication Information
Journal of Korean Elementary Science Education / v.38, no.1, 2019 , pp. 73-86 More about this Journal
Abstract
The purpose of this study is to investigate the characteristics of problem solving strategies that gifted students use in science inquiry problem. The subjects of the study are the notes and presentation materials that the 15 team of elementary and junior high school students have solved the problem. They are a team consisting of 27 elementary gifted and 29 middle gifted children who voluntarily selected topics related to dimple among the various inquiry themes. The analysis data are the observations of the subjects' inquiry process, the notes recorded in the inquiry process, and the results of the presentations. In this process, the knowledge related to dimple is classified into the declarative knowledge level and the process knowledge level, and the strategies used by the gifted students are divided into general strategy and supplementary strategy. The results of this study are as follows. First, as a result of categorizing gifted students into knowledge level, six types of AA, AB, BA, BB, BC, and CB were found among the 9 types of knowledge level. Therefore, gifted students did not have a high declarative knowledge level (AC type) or very low level of procedural knowledge level (CA type). Second, the general strategy that gifted students used to solve the dimple problem was using deductive reasoning, inductive reasoning, finding the rule, solving the problem in reverse, building similar problems, and guessing & reviewing strategies. The supplementary strategies used to solve the dimple problem was finding clues, recording important information, using tables and graphs, making tools, using pictures, and thinking experiment strategies. Third, the higher the knowledge level of gifted students, the more common type of strategies they use. In the case of supplementary strategy, it was not related to each type according to knowledge level. Knowledge-based learning related to problem situations can be helpful in understanding, interpreting, and representing problems. In a new problem situation, more problem solving strategies can be used to solve problems in various ways.
Keywords
scientific problem solving; gifted students; general strategy; supplementary strategy; declarative knowledge; procedural knowledge;
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Times Cited By KSCI : 3  (Citation Analysis)
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1 Jang, B., Lee, D., Kim, N. & Lee, M. (1999). A study on the development of science program for the gifted children of elementary school. Journal of Research in Science Education: Chuncheon National University of Education Publication, 23, 21-34.
2 Kang, U., Kim, S. & Park, J. (2009). Analysis of features related to authentic science inquiry appear in open-ended activities of the elementary science-gifted students. Journal of Gifted/Talented Education, 19(3), 647-667.
3 Kim, C. (1998a). Everyday science problem solving processes of high ability elementary students in science. Journal of Korean Elementary Science Education, 17(1), 75-87.
4 Kim, G. (1998b). Modern epistemology [현대인식론]. Minumsa.
5 Kim, H. & Song, J. (2012). Searching for effective strategies on teaching open-inquiry - Based on cases of a science high school carrying out KYPT problem solving activities -. Journal of the Korean Association for Science Education, 32(10), 1489-1501.   DOI
6 Kim, M. & Kim, Y. (2015). An analysis of the verbal interaction patterns of science-gifted students in science inquiry activity, Journal of the Korean Association for Science Education, 35(2), 333-342.   DOI
7 Kim, S. (1995). The strategies and evaluation methods of problem solving. The Journal of Educational Research in Mathematics, 5(1), 79-89.
8 Kim, Y. (1999). Thinking skills: Theory, development and class. Gyoyuggwahagsa.
9 Ko, S. & No, J. (2007). A study on student's processes of problem solving using open-ended geometric problems in the middle school. Journal of the Korean School Mathematics, 10(3), 303-322.
10 Krulik, S. & Rudnick, J. A. (1987). Problem solving: A handbook for senior highschool teacher (2nd ed.). Needham Heights, MA: Allyn and Bacon.
11 Kwon, Y., Jeong, J., Park, Y. & Kang, M. (2003). Focused on inductive, adductive, and deductive processes = A philosophical study on the generating process of declarative scientific knowledge. Journal of the Korean Association for Science Education, 23(3), 215-228.
12 Kwon, Y. & Kang, H. (2015). Problem solving strategy for Goldberg machine task according to the cognitive styles of elementary gifted students group. Journal of Gifted/Talented Education, 25(1), 77-93.   DOI
13 Lee, D. & Lee, K. (2015). Development and application of forensics science-based teaching-learning program for improvement of science creative problem solving ability in high school students. Cheonglam Journal of Science Education Research, Korea National University of Education, 21(2), 43-58.
14 Lim, G. (2010). Science problem solving process analysis of the elementary science gifted student. Master's thesis, Daegu National University of Education.
15 Lee, U. (2010). A case study on characteristics of science writing heuristic and verbal interactions in problemsolving processes of scientifically gifted students. Doctor's thesis, Korea National University of Education.
16 Lee, Y. (2014). Problem solving process of elementary science gifted students' according to the type of problem. Master's thesis, Gyeongin National University of Education.
17 Lee, Y. (2015). Analysis of the verbal interaction in small groups of middle school science-gifted according to their personality and inquiry types. Master's thesis, Ajou University.
18 Ministry of Education (2015). 2009 revised curriculum science teacher guide 3-1. Ministry of Education Press.
19 Luger, G. F., Johnson, P., Stern C., Newman, J. E. & Yeo, R. (1994). Cognitive science: The science of intelligent system. San Diago, CA: US Academic Press.
20 Mayer, R. E. (1999). Problem solving. In M. A. Runco & S. R. Pritzker (Eds.), Encyclopedia of creativity (Vol. 2, pp. 295-300). San Diego, CA: Acadmic Press.
21 Nam, S. (2009). A study on the unstructured science problem solving strategy of science gifted and general children. Master's thesis, Gyeongin National University of Education.
22 Newell, A. & Simon, H. A. (1972). Human problem solving. Englewood Cliffs, NJ: Prentive-Hall.
23 Oh, P. (2006). Rule-Inferring strategies for adductive reasoning in the process of solving an earth-environmental problem. Journal of the Korean Association for Science Education, 26(4), 546-558.
24 Roychoudhury, A. & Roth, W. M. (1996). Interactions in an open-inquiry physics laboratory. International Journal of Science Education, 18(4), 423-446.   DOI
25 Yoo, M. (2012). A case study on the science-gifted students verbal interaction in small group inquiry activity according to grouping method considering MBTI personality type. Journal of Science Education for the Gifted, 4(1), 43-64.
26 Shim, K., Kim, H. & Chung. J. (2004). Conceptual changes of middle school students on the motion of the moon using the cognitive conflict instructional model. Journal of the Korean Earth Science Society, 25(5), 348-363.
27 Smith, M. U. & Good, R. (1984). Problem solving and classical genetics: Successful versus unsuccessful performance. Journal of Research in Science Teaching, 21(9), 895-912.   DOI
28 Son, J. (2009). The study of scientifically gifted students scientific thinking and creative problem solving ability through science writing. Journal of Science Education for the Gifted, 1(3), 21-32.
29 Song, Y. & Kim, B. (2010). The development of an instrument for scientific attitudes in school, home and social situations and selection of scientific attitude elements. Journal of the Korean Association for Science Education, 30(4), 375-388.   DOI
30 Woods, D. R (1989). Problem solving in practice. In. D.L. Gabel (Ed.), What research says to the science teacher: Problem solving (pp. 97-121). Washington, DC: National Science Teachers Association.
31 Hayes, J. R. (1989). The complete problem solver (2nd ed.). Hillsdale: Lawrence Erlbaum Associates.
32 Camacho, M. & Good, R. (1989). Problem solving and chemical equilibrium: Successful versus unsuccessful performance. Journal of Research in Science Teaching, 26(3), 251-272.   DOI
33 Charles, R. & Lester, F. (1982). Teaching problem solving: What, why & how. California: Dale Seymour Publication.
34 Chinn, C. A. & Malhotra, B. A. (2002). Epistemological authentic inquiry in schools. A theoretical framework for evaluating inquiry task. Science Education, 86(2), 175-218.   DOI
35 Hong, M. (1995). Influence of characteristics of problems and problem solvers on chemistry. Doctor's thesis, Seoul University.